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Three-Dimensional Numerical Modeling of a Low-Temperature Sabatier Reactor for a Tandem System of CO<sub>2</sub> Methanation and Polymer Electrolyte Membrane Water Electrolysis
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- NAKAJIMA Hironori
- Department of Mechanical Engineering, Faculty of Engineering, Kyushu University
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- SHIMA Asuka
- Research and Development Directorate, Japan Aerospace Exploration Agency
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- INOUE Mitsuhiro
- Hydrogen Isotope Research Center, Organization for Promotion of Research, University of Toyama
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- ABE Takayuki
- Hydrogen Isotope Research Center, Organization for Promotion of Research, University of Toyama
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- MATSUMOTO Hiroshige
- International Institute of Carbon-Neutral Energy Research, Kyushu University
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- MENDOZA-HERNANDEZ Omar Samuel
- Department of Spacecraft Engineering, Institute of Space and Astronautical Science, Japan Aerospace Exploration Agency
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- SONE Yoshitsugu
- Department of Spacecraft Engineering, Institute of Space and Astronautical Science, Japan Aerospace Exploration Agency The Graduate University for Advanced Studies (SOKENDAI)
Bibliographic Information
- Other Title
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- Three-dimensional numerical modeling of a low-temperature Sabatier reactor for a tandem system of CO2 methanation and polymer electrolyte membrane water electrolysis
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Description
<p>The Sabatier reaction, which converts CO2 and H2 into CH4 and H2O (methanation), is an attractive way to produce a hydrogen carrier for renewable energy and CO2 recycling. Also, for air revitalization in space missions, water electrolysis provides not only O2, but also H2, which can hydrogenate metabolic CO2 from human respiration using the Sabatier reaction, producing H2O for O2 regeneration with the electrolysis. In this study, we have developed a three-dimensional finite element model of a test tandem cell combining a low-temperature Sabatier reactor working at around 220 °C with a proton exchange membrane water electrolyzer at around 120 °C. The model with our developed Sabatier reaction catalyst demonstrated that appropriate heat balance between the reactor and electrolyzer establishes a CO2 conversion above 90 % and thermal self-sustainability. An appropriate thermal insulator between the reactor and electrolyzer maintains them at predetermined temperatures. The thermal analysis also shows thermal self-sustainability for a plurality of the tandem cells, simulating a cell in a stack. Exergy loss ascribed to the entropy production rate with the temperature drop between the Sabatier reactor and electrolyzer is also evaluated.</p>
Journal
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- Electrochemistry
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Electrochemistry 90 (6), 067008-067008, 2022-06-29
The Electrochemical Society of Japan
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Keywords
Details 詳細情報について
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- CRID
- 1390292561183899776
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- ISSN
- 21862451
- 13443542
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- Text Lang
- en
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- Data Source
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- JaLC
- Crossref
- OpenAIRE
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- Abstract License Flag
- Allowed